Science Standards of Learning
Curriculum Framework
Biology
Commonwealth of Virginia
Board of Education
Richmond, Virginia
© 2003
Standard BIO.1 a, b, c, i, j, mThe student will plan and conduct investigations in which
a) observations of living organisms are recorded in the lab and in the field;
b) hypotheses are formulated based on direct observations and information from scientific literature;
c) variables are defined and investigations are designed to test hypotheses;
i) appropriate technology including computers, graphing calculators, and probeware, is used for gathering and analyzing data and communicating results;
j) research utilizes scientific literature; and
m) a scientific viewpoint is constructed and defended (the nature of science).
Essential Understandings / Essential Knowledge and Skills
· Active participation in scientific investigations is necessary to develop an understanding of biology as an experimental science.
· The continual use and development of cognitive and manipulative skills associated with the formulation of the scientific explanations is important.
· The design of sound scientific experiments relies on systematic preliminary observations and data collected in the laboratory and in the field, as well as on a knowledge base gained from an examination of related scientific literature. Prior establishment of an adequate knowledge base is essential before hypotheses can be developed and tested. / Skills
· Collect preliminary observations, both qualitative and quantitative.
· Make clear distinctions among observations, inferences, and predictions.
· Formulate hypotheses based on cause-and-effect relationships.
· Justify hypotheses based on both preliminary observations and scientific literature.
· Identify the independent variable (IV) and the values of the IV that will be used in the experiment.
· Select dependent variables that allow collection of quantitative data.
Standard BIO.1 a, b, c, i, j, m (continued)
Essential Understandings / Essential Knowledge and Skills
· It is typical for scientists to disagree with one another about the interpretation of evidence or a theory being considered. This is partly a result of the unique background (social, educational, etc.) that individual scientists bring to their research.
· Because of this inherent subjectivity, scientific inquiry involves evaluating the results and conclusions proposed by other scientists. / · Use appropriate technology for data collection, including probeware interfaced to a graphing calculator and/or computer, microscope, video microscope, or digital camera with image processing software.
· Identify variables that must be held constant.
· Establish controls as appropriate.
· Write clear, replicable procedures.
· Record quantitative data in clearly labeled tables with units.
· Include labeled diagrams in the data record.
· Critically examine and discuss the validity of results reported in scientific literature and databases.
· Explain how competing scientific theories based on the same observations can be equally valid.
· Recognize that in order to ensure the validity of scientific investigations, other members of the scientific community must evaluate the work.
Standard BIO.1 d, e, f, g
The student will plan and conduct investigations in which
d) graphing and arithmetic calculations are used as tools in data analysis;
e) conclusions are formed based on recorded quantitative and qualitative data;
f) sources of error inherent in experimental design are identified and discussed; and
g) validity of data is determined.
Essential Understandings / Essential Knowledge and Skills
· The analysis of evidence and data is essential in order to make sense of the content of science.
· Multiple data manipulation and analysis strategies are available to help explain results of quantitative investigations.
· Data and evidence should come from a variety of sources, including student investigation, peer investigation, and databases. / Skills
· Determine the range, mean, and values for data, using a graphing calculator and/or computer spreadsheet software.
· Plot data graphically, showing independent and dependent variables.
· Describe linear mathematical functions from the data where appropriate, using a graphing calculator and/or computer spreadsheet.
· Discuss accuracy, confidence, and sources of experimental error based on number of trials and variance in the data.
· Recognize and discuss contradictory or unusual data.
Standard BIO.1 h, k, l
The student will plan and conduct investigations in which
h) chemicals and equipment are used in a safe manner;
k) differentiation is made between a scientific hypothesis and theory; and
l) alternative scientific explanations and models are recognized and analyzed.
Essential Understandings / Essential Knowledge and Skills
Knowledge
· A hypothesis can be supported, modified, or rejected based on collected data. A hypothesis is a tentative explanation that accounts for a set of facts and that can be tested by further investigation. A theory is an explanation of a large body of information, experimental and inferential, and serves as an overarching framework for numerous concepts. It is subject to change as new evidence becomes available.
Skills
· Use evidence, apply logic, and construct an argument for conclusions based on reported data.
· Determine the extent to which data supports/does not support a hypothesis, and propose further hypotheses and directions for continued research.
Standard BIO.2 a, b, c, d
The student will investigate and understand the history of biological concepts. Key concepts include
a) evidence supporting the cell theory;
b) scientific explanations of the development of organisms through time (biological evolution);
c) evidence supporting the germ theory of infectious disease; and
d) the development of the structural model of DNA.
Essential Understandings / Essential Knowledge and Skills
· In order to develop an understanding of biology as an experimental science, there must be knowledge of how scientific discoveries are made and how these discoveries have led to the accumulation of knowledge that is presented in textbooks. A historical perspective encourages the examination of concrete examples in the context from which they were developed. / Knowledge
· The development and refinement of magnifying lenses and light microscopes made the observation and description of microscopic organisms and living cells possible.
· The development of the cell theory was accelerated by the ability to make observations on a microscopic level.
· The cell theory states that all living things are composed of cells and that cells come from other cells by the process of cell reproduction.
· Continued advances in microscopy allowed observation of cell organelles and ultrastructure. Current technology allows the observation of cellular processes underlying both cell structure and function.
· Scientists have developed hypotheses about conditions on early Earth that could have led to the formation of the first organic molecules, early self-replicating molecules, the source of free oxygen in Earth’s atmosphere, and the appearance of prokaryotic and later eukaryotic cells.
Standard BIO.2 a, b, c, d (continued)
Essential Understandings / Essential Knowledge and Skills
· Natural selection is a process by which organisms with traits well suited to an environment survive and reproduce at a greater rate than organisms less suited to that environment.
· Throughout history, people have created explanations for disease.
· Pasteur’s and Koch’s experimentation and hypotheses led to an understanding of the presence of microorganisms and their relationship to diseases.
· The introduction of the germ theory led to the understanding that many diseases are caused by microorganisms.
· Changes in health practices have resulted from the acceptance of the germ theory of disease.
· Modern health practices emphasize sanitation, the safe handling of food and water, aseptic techniques to keep germs out of the body, and the development of vaccinations and other chemicals and processes to destroy microorganisms.
· Once DNA was shown to be the genetic material, a race among scientists took place to work out its structure.
· Studies of the amounts of each DNA base in different organisms led to the concept of complementary base-paring.
Standard BIO.2 a, b, c, d (continued)
Essential Understandings / Essential Knowledge and Skills
· Interpretations of X-ray photographs of DNA were used to describe the shape and dimensions of the molecule. An analysis of this and other available data led to a structural model for the DNA double helix.
· The double helix model explained how heredity information is transmitted and provided the basis for an explosion of scientific research in molecular genetics.
Standard BIO.2 e
The student will investigate and understand the history of biological concepts. Key concepts include
e) the collaborative efforts of scientists, past and present.
Essential Understandings / Essential Knowledge and Skills
· The scientific establishment sometimes rejects new ideas, and new discoveries often spring from unexpected findings.
· Scientific knowledge usually grows slowly through contributions from many different investigators from diverse cultures. / Knowledge
· Science depends on experimental and observational confirmation and is subject to change as new evidence becomes available.
Standard BIO.3 a
The student will investigate and understand the chemical and biochemical principles essential for life. Key concepts include
a) water chemistry and its impact on life processes.
Essential Understandings / Essential Knowledge and Skills
· Water is essential for life on Earth.
· About two thirds of the mass of a cell is made up of water, and most of the biochemical processes of life occur in water solutions. / Knowledge
· Water molecules are both cohesive and adhesive due to the nature of bonding (polar covalent and hydrogen bonding).
· Water is able to absorb large amounts of heat. As a result, lakes and oceans stabilize air and land temperatures.
· Water absorbs heat when it evaporates, allowing organisms to release excess heat.
· The solid form of water, ice, floats, preventing lakes and oceans from freezing solid.
· Water is able to dissolve many substances; therefore, the water inside and outside of cells is able to carry nutrients into and around cells and wastes away from cells.
· The pH scale ranges from 0 to 14. The pH of pure water is 7. Substances added to water can lower or raise the pH. A solution with a pH below 7 is acidic. A solution with a pH above 7 is basic.
· Organisms can tolerate only small changes in pH because every cell has a particular pH at which it functions best. For example, changes in pH cause changes in enzyme conformation, resulting in a change in activity.
Standard BIO.3 b, c
The student will investigate and understand the chemical and biochemical principles essential for life. Key concepts include
b) the structure and function of macromolecules; and
c) the nature of enzymes.
Essential Understandings / Essential Knowledge and Skills
· Most life processes are a series of chemical reactions influenced by environmental and genetic factors.
· Inside every cell is a concentrated mixture of thousands of different macromolecules forming a variety of specialized structures that carry out cell functions, such as energy production, transport, waste disposal, synthesis of new molecules, and storage of genetic material.
· Protein molecules that are assembled in cells carry out most of the cells’ work. The function of each protein molecule depends on its specific conformation. The chemical reactions that occur inside cells are directly controlled by a large set of protein molecules called enzymes, whose functions depend on their specific shapes. / Knowledge
· The main components of a living cell are carbon, hydrogen, nitrogen, oxygen, phosphorus, and sulfur.
· Carbon atoms can easily bond to several other carbon atoms in chains and rings to form large complex molecules.
· Cells can make a variety of macromolecules from a relatively small set of monomers.
· The primary functions of carbohydrate macromolecules are to provide and store energy. The primary functions of lipid macromolecules are to insulate, store energy, and make up cell membranes.
· Nucleic acids (DNA and RNA) control cell activities by directing protein synthesis.
· Some proteins are structural (hair, nails). Others function in transport (hemoglobin), movement (muscle fibers and cytoskeletal elements), defense (antibodies), and regulation of cell functions (hormones and enzymes).
Standard BIO.3 b, c (continued)
Essential Understandings / Essential Knowledge and Skills
· Proteins are polymers made by linking together amino acid monomers.
· A protein’s structure depends on its specific conformation. The sequence of amino acids and the shape of the chain are a consequence of attractions between the chain’s parts.
· Each enzyme has a definite three-dimensional shape that allows it to recognize and bind with its substrate. In living cells, enzymes control the rate of metabolic reaction by acting as catalysts.
· Most cells function best within a narrow range of temperature and pH. At very low temperatures, reaction rates are too slow. High temperatures or extremes of pH can irreversibly change the structure of proteins and alter their function.
Standard BIO.3 d
The student will investigate and understand the chemical and biochemical principles essential for life. Key concepts include
d) the capture, storage, transformation, and flow of energy through the processes of photosynthesis and respiration.
Essential Understandings / Essential Knowledge and Skills
· Plant cells and many microorganisms use solar energy to combine molecules of carbon dioxide and water into complex, energy-rich organic compounds and release oxygen into the environment.
· The process of photosynthesis provides a vital connection between the sun and the energy needs of living systems.
· The breakdown of nutrient molecules enables all cells to store energy in specific chemicals that are used to carry out the life functions of the cell. / Knowledge
· Photosynthesis and cell respiration are complementary processes for cycling carbon dioxide and oxygen as well as transferring energy in ecosystems.
· During photosynthesis, cells trap energy from sunlight with chlorophyll and use the energy, carbon dioxide and water to produce energy-rich organic molecules (glucose) and oxygen.
· During cell respiration, eukaryotic cells “burn” organic molecules with oxygen, which produces energy, carbon dioxide, and water.
· Light is the initial source of energy for most communities.
· Photosynthesis involves an energy conversion in which light energy is converted to chemical energy in specialized cells. These cells are found in autotrophs such as plants and some protists.
· Cells release the chemical energy stored in the products of photosynthesis. This energy is transported within the cell in the form of ATP.